We consider the problem of energy-efficient broadcasting on dense ad-hoc networks. Ad-hoc networks are generally modeled using random geometric graphs (RGGs). Here, nodes are deployed uniformly in a square area around the origin, and any two nodes which are within Euclidean distance of $1$ are assumed to be able to receive each other's broadcast. A source node at the origin encodes $k$ data packets of information into $n\ (>k)$ coded packets and transmits them to all its one-hop neighbors. The encoding is such that, any node that receives at least $k$ out of the $n$ coded packets can retrieve the original $k$ data packets. Every other node in the network follows a probabilistic forwarding protocol; upon reception of a previously unreceived packet, the node forwards it with probability $p$ and does nothing with probability $1-p$. We are interested in the minimum forwarding probability which ensures that a large fraction of nodes can decode the information from the source. We deem this a \emph{near-broadcast}. The performance metric of interest is the expected total number of transmissions at this minimum forwarding probability, where the expectation is over both the forwarding protocol as well as the realization of the RGG. In comparison to probabilistic forwarding with no coding, our treatment of the problem indicates that, with a judicious choice of $n$, it is possible to reduce the expected total number of transmissions while ensuring a near-broadcast.
翻译:我们考虑在密集的自动热量网络上进行节能广播的问题。 自动热量网络一般使用随机几何图( RGG) 进行模拟。 这里, 节点在源头周围的平方区域被统一部署, 任何位于Euclidean距离内$美元之间的两个节点都假定能够接收到对方的广播。 源头的源节点将数据包编码为$k美元( >k) 代码包, 并将其传送到所有单位邻居。 编码是这样的: 从美元编码包中至少收到美元的任何节点都可以检索原始的美元数据包。 网络中每个其他节点都遵循一个概率性转发协议; 收到一个先前未接收的包时, 节点将数据包的概率提前到$( >k) 的概率。 我们感兴趣的是最小的转发概率, 保证大量节点能够将信息从源头部分解码解析出信息从$的源头解析出。 我们认为这个预估测值的预估值与预估值的预估值 。